22 research outputs found
Mesenchymal Stem Cells Delivery in Individuals with Different Pathologies: Multimodal Tracking, Safety and Future Applications
Bioluminescence; Radioiodine therapy; TransdifferentiationBioluminiscencia; Terapia con yodo radiactivo; TransdiferenciaciónBioluminescència; Teràpia amb iode radioactiu; TransdiferenciacióDue to their ease of isolation and their properties, mesenchymal stem cells (MSCs) have been widely investigated. MSCs have been proved capable of migration towards areas of inflammation, including tumors. Therefore, they have been suggested as vectors to carry therapies, specifically to neoplasias. As most of the individuals joining clinical trials that use MSCs for cancer and other pathologies are carefully recruited and do not suffer from other diseases, here we decided to study the safety and application of iv-injected MSCs in animals simultaneously induced with different inflammatory pathologies (diabetes, wound healing and tumors). We studied this by in vitro and in vivo approaches using different gene reporters (GFP, hNIS, and f-Luc) and non-invasive techniques (PET, BLI, or fluorescence). Our results found that MSCs reached different organs depending on the previously induced pathology. Moreover, we evaluated the property of MSCs to target tumors as vectors to deliver adenoviruses, including the interaction between tumor microenvironment and MSCs on their arrival. Mechanisms such as transdifferentiation, MSC fusion with cells, or paracrine processes after MSCs homing were studied, increasing the knowledge and safety of this new therapy for cancer.This research was supported by Instituto de Salud Carlos III (ISCIII) (PI19/01007 and DTS21/00130) and by Fondo Europeo de Desarrollo Regional (Feder) “Una manera de hacer Europa”. We also thank CIBER-BBN and CIBERONC an initiative funded by the VI National R&D&i Plan 2008–2011 financed by the Instituto de Salud Carlos III (ISCIII) with the assistance of the European Regional Development Fund. This study was also partially funded by the Aragon Government (Ph.D. Grant No.r B054/12) and cofounded by Aragon/FEDER 2014–2020 “Building Europe from Aragon”. This research was funded by Spanish Ministerio de Economía y Competitividad and European Regional Development Fund (FEDER) SAF2015-69964-R, RTI2018-099343-B-100 and from the CiberOnc by Instituto de Salud Carlos III (to ADlV)
Uveal vs. cutaneous melanoma. Origins and causes of the differences
El pdf del artículo es la versión post-print.-- et al.Melanoma is a malignant tumour derived from melanocytes (dendritic cells originated from the neural crest and capable to produce melanin synthesis) that could be established on the skin or less frequently on the uvea. The cellular origin from both kind of melanoma seems to be the same but the melanocytes migrates to the epithelia for cutaneous melanoma, while for uveal melanoma, they migrate to mesodermic tissues. Despite the common origin, both melanomas show extreme differences in their metastatic potential, clinical response to treatments, immune response and genetic alterations. We will describe some of those differences in this review. © Feseo 2008.Supported by an unrestricted educational grant from GlaxoSmithKline.Peer Reviewe
Tissue-derived mesenchymal stromal cells used as vehicles for anti-tumor therapy exert different in vivo effects on migration capacity and tumor growth
This is an Open Access article distributed under the terms of the Creative Commons Attribution License.-- et al.[Background]: Mesenchymal stem cells (MSCs) have been promoted as an attractive option to use as cellular delivery vehicles to carry anti-tumor agents, owing to their ability to home into tumor sites and secrete cytokines. Multiple isolated populations have been described as MSCs, but despite extensive in vitro characterization, little is known about their in vivo behavior.The aim of this study was to investigate the efficacy and efficiency of different MSC lineages derived from five different sources (bone marrow, adipose tissue, epithelial endometrium, stroma endometrium, and amniotic membrane), in order to assess their adequacy for cell-based anti-tumor therapies. Our study shows the crucial importance of understanding the interaction between MSCs and tumor cells, and provides both information and a methodological approach, which could be used to develop safer and more accurate targeted therapeutic applications.
[Methods]: We first measured the in vivo migration capacity and effect on tumor growth of the different MSCs using two imaging techniques: (i) single-photon emission computed tomography combined with computed tomography (SPECT-CT), using the human sodium iodine symporter gene (hNIS) and (ii) magnetic resonance imaging using superparamagnetic iron oxide. We then sought correlations between these parameters and expression of pluripotency-related or migration-related genes.
[Results]: Our results show that migration of human bone marrow-derived MSCs was significantly reduced and slower than that obtained with the other MSCs assayed and also with human induced pluripotent stem cells (hiPSCs). The qPCR data clearly show that MSCs and hiPSCs exert a very different pluripotency pattern, which correlates with the differences observed in their engraftment capacity and with their effects on tumor growth.
[Conclusion]: This study reveals differences in MSC recruitment/migration toward the tumor site and the corresponding effects on tumor growth. Three observations stand out: 1) tracking of the stem cell is essential to check the safety and efficacy of cell therapies; 2) the MSC lineage to be used in the cell therapy needs to be carefully chosen to balance efficacy and safety for a particular tumor type; and 3) different pluripotency and mobility patterns can be linked to the engraftment capacity of the MSCs, and should be checked as part of the clinical characterization of the lineage.This work was supported by FIS (PI080750), DGA (PI041/08, B84, PI086/09), MMA Fund (ICS/08/0050), PROMETEO/2008/163; CTQ-2010-20960-C02-02; S2010/BMD-2349, PIPAMER-0912, and PIPAMER-1214. CB-L was funded by fellowships ICS/08/0050 and DGA PI-086/09, GM by PIPAMER-0912, and PMD by the Araid Fund.Peer Reviewe
Tissue-derived mesenchymal stromal cells used as vehicles for anti-tumor therapy exert different in vivo
Background: Mesenchymal stem cells (MSCs) have been promoted as an attractive option to use as cellular delivery vehicles to carry anti-tumor agents, owing to their ability to home into tumor sites and secrete cytokines. Multiple isolated populations have been described as MSCs, but despite extensive in vitro characterization, little is known about their in vivo behavior. The aim of this study was to investigate the efficacy and efficiency of different MSC lineages derived from five different sources (bone marrow, adipose tissue, epithelial endometrium, stroma endometrium, and amniotic membrane), in order to assess their adequacy for cell-based anti-tumor therapies. Our study shows the crucial importance of understanding the interaction between MSCs and tumor cells, and provides both information and a methodological approach, which could be used to develop safer and more accurate targeted therapeutic applications. Methods: We first measured the in vivo migration capacity and effect on tumor growth of the different MSCs using two imaging techniques: (i) single-photon emission computed tomography combined with computed tomography (SPECT-CT), using the human sodium iodine symporter gene (hNIS) and (ii) magnetic resonance imaging using superparamagnetic iron oxide. We then sought correlations between these parameters and expression of pluripotency-related or migration-related genes. Results: Our results show that migration of human bone marrow-derived MSCs was significantly reduced and slower than that obtained with the other MSCs assayed and also with human induced pluripotent stem cells (hiPSCs). The qPCR data clearly show that MSCs and hiPSCs exert a very different pluripotency pattern, which correlates with the differences observed in their engraftment capacity and with their effects on tumor growth. Conclusion: This study reveals differences in MSC recruitment/migration toward the tumor site and the corresponding effects on tumor growth. Three observations stand out: 1) tracking of the stem cell is essential to check the safety and efficacy of cell therapies; 2) the MSC lineage to be used in the cell therapy needs to be carefully chosen to balance efficacy and safety for a particular tumor type; and 3) different pluripotency and mobility patterns can be linked to the engraftment capacity of the MSCs, and should be checked as part of the clinical characterization of the lineage
Using living cells to transport therapeutic genes for cancer treatment
One of the key problems in cancer gene therapy is the inefficient delivery of therapeutic transgenes to tumour sites, after the systemic injection of the viral vector. Hence, new vector discovery is extremely important for the improvement of gene therapy results. Previously, mammalian cells were proposed as new vector systems; however with recent advances in stem cell research this modality makes them more suitable candidates. Tumours are composed of both malignant and benign cells. As >benign> cell types are able to form blood vessels, and stroma, it has been hypothesised that exogenously administrated cells of a different kind would preferentially engraft at the stromal tumour site and could deliver cancer gene therapy vectors to tumours.Work at P.M.D.’s lab is supported by grants from FISs (PI080750), DGA (PI041/08, B84, PI086/09), Fundación MMA (ICS/08/0050) and PIPAMER 0912. C.L.T.R. is funded by grant DGA PI041/08. C.B.L. was funded by grants ICS/08/0050 and DGA PI 086/09.Peer Reviewe
Gold nanoparticle coatings as efficient adenovirus carriers to non-infectable stem cells
Mesenchymal stem cells (MSCs) are adult pluripotent cells with the plasticity to be converted into different cell types. Their self-renewal capacity, relative ease of isolation, expansion and inherent migration to tumors, make them perfect candidates for cell therapy against cancer. However, MSCs are notoriously refractory to adenoviral infection, mainly because CAR (Coxsackie-Adenovirus Receptor) expression is absent or downregulated. Over the last years, nanoparticles have attracted a great deal of attention as potential vehicle candidates for gene delivery, but with limited effects on their own. Our data showed that the use of positively charged 14 nm gold nanoparticles either functionalized with arginine–glycine–aspartate (RGD) motif or not, increases the efficiency of adenovirus infection in comparison to commercial reagents without altering cell viability or cell phenotype. This system represents a simple, efficient and safe method for the transduction of MSCs, being attractive for cancer gene and cell therapies.This work was supported by Araid Fund; by the Government of Aragon through a PhD grant (B054/12); Fundación Mutua Madrileña Automovilística (MMA); Instituto de Salud Carlos III, and ERANET-NANOSCIERA NANOTRUCK projects.Peer reviewe
Gold nanoparticle coatings as efficient adenovirus carriers to non-infectable stem cells
Mesenchymal stem cells (MSCs) are adult pluripotent cells with the plasticity to be converted into different cell types. Their self-renewal capacity, relative ease of isolation, expansion and inherent migration to tumors, make them perfect candidates for cell therapy against cancer. However, MSCs are notoriously refractory to adenoviral infection, mainly because CAR (Coxsackie-Adenovirus Receptor) expression is absent or downregulated. Over the last years, nanoparticles have attracted a great deal of attention as potential vehicle candidates for gene delivery, but with limited effects on their own. Our data showed that the use of positively charged 14 nm gold nanoparticles either functionalized with arginine–glycine–aspartate (RGD) motif or not, increases the efficiency of adenovirus infection in comparison to commercial reagents without altering cell viability or cell phenotype. This system represents a simple, efficient and safe method for the transduction of MSCs, being attractive for cancer gene and cell therapies.This work was supported by Araid Fund; by the Government of Aragon through a PhD grant (B054/12); Fundación Mutua Madrileña Automovilística (MMA); Instituto de Salud Carlos III, and ERANET-NANOSCIERA NANOTRUCK projects.Peer reviewe
Glioblastoma: Análisis molecular y sus implicancias clínicas
El glioblastoma multiforme (GB) es el tumor cerebral primario del sistema nervioso central (SNC) más frecuente y más letal en la edad adulta. La evidencia epidemiológica indica que su incidencia es menor en la raza hispana. El tratamiento quirúrgico es la opción terapéutica preferente. Recientemente se han introducido nuevas estrategias que incrementan el volumen de resección. El uso de quimioterapia y radioterapia concurrentes mejora la supervivencia de los pacientes, aunque se asocia a toxicidad. La mejora en la comprensión de la biología molecular del GB ha permitido la identificación de biomarcadores predictivos de respuesta terapéutica y pronóstico, así como la identificación de dianas terapéuticas que han permitido el desarrollo de nuevas estrategias en el tratamiento de estos tumores. Entre los biomarcadores actualmente disponibles se encuentran la codelección 1p/19q, la mutación de IDH y la metilación del promotor O6- metilguanina DNA-metiltransferasa. La identificación de dianas terapéuticas permite el desarrollo de nuevas drogas y su evaluación posterior en ensayos clínicos, aunque ninguna de ellas ha sido validada prospectivamente en ensayos clínicos de fase II